Single crystal calcium fluoride for photolithography

ABSTRACT

A calcium fluoride single crystal for photolithography, wherein a critical resolved shear stress (τ c ) in a &lt;1 1 0&gt; direction on a {0 0 1 } plane of the calcium fluoride single crystal is approximately equal to or larger than a shear stress (τ) expressed by τ=1.5E−2·exp(3E3·T −1 ), where r is shear stress (MPa) and T is average temperature (K) of the calcium fluoride.

This application is a divisional application of copending U.S. patent application Ser. No. 10/657,166, filed Sep. 9, 2003.

This application claims benefit of foreign priority based on Japanese Patent Application No. 2002-266905, filed on Sep. 12, 2002, which is hereby incorporated by reference herein in it entirety as if fully set forth herein.

BACKGROUND OF THE INVENTION

The present invention relates to a method of manufacturing a calcium fluorite (“CaF₂”) single crystal and a CaF₂ single crystal. The present invention also relates to an optical system that uses, as a light source, ultraviolet light from an excimer laser, such as KrF, ArF, F₂ and Ar₂, and an exposure apparatus for manufacturing semiconductors, and a device fabrication method.

No end to a demand for higher integration of semiconductor integrated circuits has required a higher level performed for an exposure apparatus, particularly, that of a projection optical system. While resolution in the exposure apparatus may improve along with an increased numerical aperture (“NA”) of the projection optical system, the higher NA makes a depth of focus smaller. Thus, the NA cannot be increased beyond a predetermined amount, and a shorter wavelength is required for a higher resolution.

While the excimer laser, such as a KrF (having a wavelenght of 248 nm), an ArF (having a wavelength of 193 nm) and an F₂ (having a wavelength of 157 nm), has been regarded as a prospective light source for future exposure apparatuses for this reason, most conventionally used glass materials are not compatible with a shortened wavelength of the light source. Fluoride crystal is used as a lens material, and a CaF₂ crystal, etc., has been developed. A single crystal type CaF₂ is used for exposure apparatuses so as to eliminate the influence of grain boundary and crystal orientation; a CaF₂ single crystal having a predetermined size generally grows in a single crystal growth furnace.

While CaF₂ for exposure apparatuses requires high quality in aspects of light transmission performance, durability, large aperture, uniform refractive index, birefringence, etc., the most concerned issue is to reduce birefringence. Preferably, the birefringence of CaF₂ has a difference in an optical path and is below 1 nm/cm for exposure apparatuses.

It is known that annealing after crystal growth is effective in reducing birefringence in a grown CaF₂ single crystal. This process may reduce the birefringent index by heating and maintaining CaF₂ at a high temperature, above 1000° C. However, when a cooling process after annealing provides rapid cooling, the birefringent index disadvantageously increases again and, thus, the cooling rate should be made low. On the other hand, the low cooling rate itself would lead to a long processing time and remarkably deteriorate productivity. Therefore, an optimization of the cooling rate is important.

Optimal cooling rates for various sized CaF₂, which have been calculated by empirical rules to maintain a low birefringent index, are disclosed in Japanese Patent Application Publication Nos. 11-240798 and 11-240787. In this case, such cooling is also disclosed as a means for increased productivity, which combines some cooling rates that have been empirically obtained for respective temperature regions, by paying attention to a fact that an increase of the birefringent index at a low temperature is less than that at a high temperature, even when CaF₂ is cooled at a higher cooling rate.

However, an approach that uses an empirical rule to obtain cooling rates that do not cause birefringence for variously differently sized CaF₂ is disadvantageous in that it is difficult to stably provide manufactured CaF₂ with good quality. In addition, it is necessary to arduously determine proper cooling rates for each size of CaF₂ single crystal to be processed. Problematically, it is difficult to confirm that no birefringence occurs after processing, the quality becomes unstable, and an excessively low cooling rate would lower the productivity.

In addition, the birefringence would occur and the productivity would lower without proper cooling even in a process that associates with heating other than annealing after CaF₂ single crystal growth. The conventional empirical approach has been hard to design a process that serves to stably provide low birefringence and high productivity.

SUMMARY OF THE INVENTION

Accordingly, it is an exemplified object of the present invention to provide a manufacturing method that manufactures CaF₂ with stable quality and good productivity, irrespective of the sizes of CaF₂, by taking into account a mechanism that increases the birefringent index of a cooling process and by clarifying a basic cooling condition that does not generate birefringence.

Another exemplary object of the present invention is to provide a CaF₂ single crystal with high quality, manufactured by the above manufacturing method.

Still another exemplary object of the present invention is to provide a CaF₂ single crystal that may be manufactured with high quality and good productivity, even when its size is so large that the birefringence is likely to increase.

Yet another exemplary object of the present invention is to provide a high-performance optical system that uses the thus provided CaF₂, an exposure apparatus that uses the optical system, and a device fabrication method that uses the exposure apparatus for a device fabrication process.

Earnest and extensive studies of the cause of an increase of birefringent index in a cooling process in order to solve these problems have discovered that a slip occurs on a given crystal plane in a CaF₂ due to the thermal stress that is generated by a temperature gradient in a CaF₂ in the cooling process, the strain caused by this slip results in residual stress after cooling, and so-called stress birefringence consequently occurs. Therefore, the instant inventors have identified a slip direction and a slip plane that generate the slip during cooling in a CaF₂ crystal, and precisely measured critical resolved shear stress as necessary shear stress to cause slip for each temperature in the cooling process.

A method of one aspect according to the present invention for manufacturing a calcium fluoride single crystal includes the step of cooling the calcium fluoride single crystal so that the maximum shear stress inside the calcium fluoride single crystal caused by thermal stress is approximately equal to or less than a critical resolved shear stress (τ_(c)) in a <1 1 0> direction of a {0 0 1} plane of the calcium fluoride single crystal.

A method of another aspect according to the present invention for manufacturing a calcium fluoride single crystal includes the step of cooling the calcium fluoride single crystal with variable cooling rates so that throughout temperature in the cooling step, maximum shear stress inside the calcium fluoride single crystal caused by thermal stress is approximately equal to or less than the critical resolved shear stress (τ_(c)) in a <1 1 0> direction on a {0 0 1} plane of the calcium fluoride single crystal and maintained to be an approximately constant ratio.

A method of another aspect according to the present invention for manufacturing a calcium fluoride single crystal includes the step of cooling the calcium fluoride single crystal so that maximum shear stress inside the calcium fluoride single crystal caused by thermal stress is 1.2 times as large as a critical resolved shear stress (τ_(c)) or less in a <1 1 0> direction on a {0 0 1} plane of the calcium fluoride single crystal.

A method of another aspect according to the present invention for manufacturing a calcium fluoride single crystal includes the step of cooling the calcium fluoride single crystal with variable cooling rates so that throughout temperature in the cooling step, maximum shear stress inside the calcium fluoride single crystal caused by thermal stress is 1.2 times as large as a critical resolved shear stress (τ_(c)) or less in a <1 1 0> direction on a {0 0 1} plane of the calcium fluoride single crystal and maintained to be an approximately constant ratio.

The cooling step may be included in a cooling step after crystal growth, a cooling step after mechanical processing of a crystal, a cleansing step of a crystal surface, or a step of coating to a crystal surface.

A crystal growth apparatus of another aspect according to the present invention includes a cooling mechanism necessary to execute the above method, an anneal apparatus for annealing a grown calcium fluoride single crystal, which includes a cooling mechanism necessary to execute the above method, an antireflection coating forming apparatus including a cooling mechanism necessary to execute the above method, and a calcium fluoride single crystal manufactured by the above method may constitute other aspects according to the present invention.

A calcium fluoride single crystal for photolithography of another aspect according to the present invention has a critical resolved shear stress (τ_(c)) in a <1 1 0> direction on a {0 0 1} surface of the calcium fluoride single crystal approximately equal to or less than the shear stress (τ) expressed by τ=1.5E−2·exp(3E3·T⁻¹), where τ is shear stress (MPa) and T is an average temperature (K) of the calcium fluoride. The calcium fluoride single crystal for photolithography may have a diameter having Φ300 mm or larger, and is used for a specific wavelength band less than 160 nm. The calcium fluoride single crystal may further include one or more types of additional elements with concentrations of 20 ppm or larger. The additional elements include strontium having a concentration of 20 to 600 ppm.

A method of another aspect according to the present invention improves a critical resolved shear stress of each slip system in the calcium fluoride single crystal by adding an additional element. The additional element may include strontium.

An optical system of another aspect according to the present invention includes an optical element made of the above calcium fluoride single crystal. An exposure apparatus of another aspect according to the present invention includes an optical system.

A device fabrication method of another aspect of this invention includes the steps of exposing a plate by using the above exposure apparatus, and performing a predetermined process for the exposed object. Claims for a device fabrication method for performing operations similar to those of the above exposure apparatus cover devices as intermediate and final products. Such devices include semiconductor chips, such as LSIs and VLSIs, CCDs, LCDs, magnetic sensors, thin film magnetic heads, and the like.

Other objects and further features of the present invention will become readily apparent from the following description of the embodiments with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a graph showing an exemplary critical resolved shear stress for each temperature in a {0 0 1}<1 1 0> slip system of a CaF₂ single crystal measured by the present invention.

FIG. 2 is a graph showing an exemplary critical resolved shear stress for each temperature in a {1 1 0}<1 −1 0> slip system of a CaF₂ single crystal measured by the present invention.

FIG. 3 is a graph showing a birefringent index and dislocation density of a CaF₂ single crystal that has been cooled so that the maximum shear stress may be at a constant ratio to a critical resolved shear stress in its primary slip system.

FIG. 4 is a graph showing exemplary changes of a critical resolved shear stress at 600° C. of the {0 0 1}<1 1 0> slip system of a CaF₂ single crystal meausred by the present invention, to which Sr has been added.

FIG. 5 is a graph that compares an exemplary post-anneal cooling rate according to the present invention with a conventional example.

FIG. 6 is a graph that compares an exemplary temperature variation of CaF₂ according to the present invention while it is cooled after anneal, with a conventional example.

FIG. 7 is a schematic diagram showing an anneal apparatus according to the present invention.

FIG. 8 is a schematic diagram showing an optical system in an inventive exposure apparatus used to manufacture semiconductors.

FIG. 9 is a flowchart for explaining a method of manufacturing a device (e.g., semiconductor chips such as ICs and LSIs, LCDs, CCDs, and the like).

FIG. 10 is a detailed flowchart of the step 104 shown in FIG. 9.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A description will be given of embodiments of the present invention.

Review of Slip System in Calcium Fluoride and Application to Manufacturing Process

The following verification tests were conducted in order to identify conditions under which a slip occurs in a CaF₂ single crystal during cooling.

A critical resolved shear stress (abbreviated as “CRSS” hereinafter) in the CaF₂ slip system was initially reviewed so as to primarily confirm the slip system and to obtain temperature dependency of CRSS. CaF₂ used for confirmation is a standard sample manufactured by annealing a single crystal grown in a manufacturing process, which is described later, and by cooling the resultant product at a low cooling rate about half the usual product in the cooling process so as to eliminate the residual strain. Table 1 shows the major impurity elements included in CaF₂. Strontium, among the impurity elements, was added as strontium fluoride when a single crystal grows: TABLE 1 (ppm) Na Mn Fe Y Ce Ba Mg Sr <0.1 <0.1 0.2 <0.01 <0.01 0.9 1.2 100

A research result has unveiled that a primary slip system in CaF₂ is {0 0 1} <1 1 0>, and a secondary slip system is {1 1 0}<1 −1 0>. It has also been unveiled that CRSS of each temperature in each slip system may be expressed by the Arrhenius equation, and all the deformations occur in a thermal activation process. A detailed research result will be given below.

A slip surface was recognized by compressing the rectangular-parallelepiped sample having a certain crystal orientation at room temperature and by bifacial-observing slip lines that appear on side surfaces. At this time, a strain speed of the sample was set to be sufficiently low, i.e., down to about 0.01%/sec, so as to realize a static stress state at the time of actual cooling.

As a result of testing, it was confirmed that an active slip system existed on a {0 0 1} surface given a compression in a <1 1 1> direction, since an angle between a slip line and a compression axis was 55° on the {1 1 0} surface, and 39° on a {1 1 2} surface. Similarly, it was confirmed that an active slip system existed on a {1 1 0} surface given a compression in the <1 0 0> direction. It was confirmed that Burgers vectors of a slip direction was expresed by <1 1 0> both on the {0 0 1} and { 1 1 0} surfaces calculated as a result of an observation of a dislocation on each slip surface using a transmission type electron microscope. Therefore, it was discovered that the major active slip systems in CaF₂ were on {0 0 1}<1 1 0>and {1 1 0}<1 −1 0>. In an attempt to calculate CRSS by taking into consideration a Schmidt factor for each slip system, it was found that the former was the primary slip system that worked with a lower shear stress and the latter was the secondary slip system.

In order to calculate CRSS in each slip system for each temperature during the cooling process, the above compression test was conducted from 200° C. to 1200° C. in an Ar atmosphere. FIG. 1 shows CRSS for each temperature with respect to the primary slip system ({0 0 1}<1 1 0>) calculated by the test. The temperature dependence of CRSS calculated by the test may be expressed in the form of the Arrhenius equation that indicates a general temperature dependency in a thermal activation process, and it is expected that deformations of CaF₂ result from the thermal activation process. The temperature dependency of CRSS shown in FIG. 1 is expressed by the following equation: τ_(c) ^(1ST)=1.5E−2·exp(3E3·T ⁻¹)   (1) where τ_(c) is CRSS [MPa] and T is temperature (K).

FIG. 2 shows temperature dependency of CRSS with respect to the secondary slip system ({1 1 0}<1 −1 0>) calculated by the test. It is also expected that the secondary slip system occurs in the thermal activation process due to the temperature dependency of CRSS. The temperature dependency of CRSS shown in FIG. 2 is expressed as follows: τ_(c) ^(2nd)=2.9E−2·exp(3E3·T ⁻¹)   (1) where τ_(c) is CRSS [MPa] and T is temperature (K).

According to the comparison between FIGS. 1 and 2, the {0 0 1}<1 1 0> slip system always has a smaller CRSS than the {1 1 0}<1 −1 0> slip system, and, thus, control over cooling may restrain slip of the CaF₂ and an increase in birefringence by maintaining the shear stress due to thermal stress generated in the CaF₂ during the cooling process within a value lower than the CRSS of the {0 0 1}<1 1 0> slip system shown in FIG. 1.

A description will be given of a method of obtaining a temperature distribution inside CaF₂ during the cooling process after annealing, etc., and for calculating shear thermal stress applied to the slip system. The thermal stress increases as the cooling rate increases and as the size of CaF₂ crystal enlarges. While the calculation should consider thermal diffusivity, specific heat, Young's modulus, and Poisson's ratio, these values vary according to temperatures and crystal orientations, and, thus, it is desirable to calculate thermal stresses by considering respective temperature dependencies and crystal orientation dependencies. Moreover, uniformity, etc., of conditions and, thus, it is preferable that the calculation considers the influence of the cooler itself.

In the embodiment according to the present invention, the entire cylindrical surface of the CaF₂ crystal was isothermal, and the maximum shear stress among thermal stress that is determined by the size of a CaF₂ crystal and cooling rate is approximated as follows by considering parameters including thermal diffusivity, specific heat, Young's modulus, and Poisson's ratio of a CaF₂ single crystal: τ_(MAX)=9E−6·exp(2E−3·T)·D ² ·R   (3) where τ_(MAX) is the maximum shear stress [MPa], D is a thickness of crystal, R is a cooling rate, and T is temperature [K] of CaF₂.

By considering the maximum shear thermal stress given by Equation (3), a cooling rate was continuously varied so that the maximum shear thermal stress generated during the cooling process in anneal exhibited a certain ratio to CRSS in the primary slip system shown in Equation (1), and the effect was confirmed.

FIG. 3 shows changes of birefringent index and dislocation density as a result of cooling so that the maximum shear stress obtained from Equation (3) occupies a certain ratio to CRSS in the primary slip system expressed by Equation (1). As shown in FIG. 3, when the maximum shear stress caused by the thermal stress is equal to or less than the CRSS of the primary slip system, both the birefrigent index 30 and dislocation density 31 become low constant values. On the other hand, when the maximum shear stress caused by the thermal stress is larger than the CRSS of the primary slip system, the dislocation density 31 increases and the birefrigent index 30 increases accordingly. This result indicates that an increase of crystal defect represented by dislocation relates to occurrence of stress birefrigence.

Thus, by maintaining the maximum shear stress caused by the thermal stress below CRSS of CaF₂ as an object to be processed in a cooling process, plastic deformation is restrained in a cooling process after a heat treatment and CaF₂ having good birefringence may be manufactured. Continuous control over cooling rates so that the maximum shear thermal stress is such a certain ratio that it may be approximately equal to or less than the CRSS of the primary slip system for each temperature during cooling may complete cooling within the shortest time while making the birefringence low, enhancing the productivity. Moreover, when the maximum shear stress calculated by Equation (3) is about 1.2 times as large as CRSS of the primary slip system, the birefringent index may be restrained below the substantially problematic account, and the shortened cooling time provides good productivity.

Effects of Deformation Tolerance of Calcium Fluoride

FIG. 4 is a view showing a relationship between added strontium content and CRSS of the (primary) {0 0 1}<1 1 0> slip system at 600° C. in a CaF₂ single crystal of a different purity, which has experienced the above heat treatment without increasing the birefrigence again. Table 2 shows respective major impurities other than strontium. A predetermined content of strontium is mixed with the CaF₂ material when the single crystal grows. TABLE 2 (ppm) Na Mn Fe Y Ce Ba Mg High Purity Material <0.1 <0.1 0.2 <0.1 <0.01 0.9 1.2 Normal Purity Material 0.5 <0.1 5.1 0.2 0.1 28 17

As shown in FIG. 4, a relatively high purity material exhibited a characteristic line 105 among a strontium-added CaF₂ base material, while a normal purity material that includes impurities to some extent exhibit a characteristic line 106.

Table 3 shows coefficient “A” in each composition when the following equation expresses temperature dependence of CRSS 9 in the {0 0 1}<1 1 0> slip system in a CaF₂ single crystal: τ_(c) =A·exp(3E3·T ⁻¹)   (4)

where τ is CRSS [MPa] and T is temperature [K]. TABLE 3 Sr concentration (ppm) 1 20 100 300 600 High Purity Material 1.3E−2 1.3E−2 1.5E−2 1.7E−2 2.0E−2 Normal Purity Material 1.4E−2 1.4E−2 1.7E−2 1.9E−2 2.2E−2

It is apparent in light of FIG. 4 that CRSS in the {0 0 1}<1 1 0> slip system improves almost proportionally to the strontium content. CRSS similarly improves by a certain ratio by an addition of strontium of each concentration for other temperatures. It may be presumed that this is because strontium dissolved in a CaF₂ single crystal, and the resistance to the slip improved. An improvement of CRSS given an additive element may improve deformation tolerance of the CaF₂. While such an improvement effect of CRSS occurs even when another element is added, strontium is particularly less influential on optical performance than other elements, as disclosed in Japanese Patent Application Publication No. 9025532, and CaF₂, including strontium of 600 ppm, is practically feasible. Therefore, strontium is an additive element appropriate to an improvement of deformation tolerance of a CaF₂ single crystal for optics purposes. An addition of strontium shown in FIG. 4 does not cause a phenomenon in that the slip system changes.

Such an improvement of deformation tolerance of CaF₂ is effective to CaF₂ for optical elements for use with a light source having a short wavelength in which influence of the birefringence becomes remarkable, in particular, manufacture of a CaF₂ lens for use with an F₂ excimer laser as light having a wavelength near 157 nm. It is also effective toward improved productivity of a large aperture CaF₂ lens for high NA, such as an aperture of Φ300 mm or larger, which needs an extremely low cooling rate in the cooling time.

Application to a Manufacturing Process

CaF₂ having low birefringence and a little residual strain was obtained and a manufacturing line having high productivity was built by optimizing annealing for CaF₂ based on information of the above series of research results. In addition, a temperature control process in the steps of processing, cleansing and forming an antireflection coating of CaF₂ may use similar cooling to the above annealing, forming CaF₂ as a lens without deteriorating performance of CaF₂. Use of a thus manufactured CaF₂ lens for an optical system would provide an optical system having excellent contrast. In addition, use of an exposure apparatus including this optical system for an exposure step in device fabrication would be able to stably provide a precise exposure process.

First Embodiment

A description will be given of a heat treatment method of a first embodiment after a CaF₂ single crystal grows.

Initially, a CaF₂ powder material was melted with a scavenger and refined so as to improve purity and bulk density. Then, the Bridgman-Stockbarger process is used to adjust a crystal orientation of a seed crystal for crystal growth in a <1 1 1> direction. A proper amount of strontium was added upon crystal growth, and strontium content in the grown single crystal was adjusted. The grown CaF₂ single crystal was cut into a cylindrical shape with a diameter of 330 mm and a thickness of 60 mm, and set in a carbon vessel in an anneal kiln. A CaF₂ single crystal is covered with a heat insulation material so as to make a surface temperature of CaF₂ uniform during heating and cooling processes, and to prevent non-uniform heat transmissions between CaF₂ subject to heat treatment and the kiln material due to contact with the kiln material, etc. The atmosphere in the kiln was drawn a vacuum, and then heated from room temperature to 1000° C. at 30° C./hour. Annealing at 1000° C. for twenty-four hours mitigated strain in the crystal.

The subsequent cooling step considers CRSS of the primary slip system ({0 0 1} <1 1 0>) in CaF₂ to be cooled using Equation (3), a size of the crystal and maximum shear stress of the crystal to be cooled, and calculates a cooling rate for each temperature so that the maximum shear stress does not exceed CRSS. A description will be given of cooling of an annealed CaF₂ single crystal of the instant embodiment using CaF₂ as an example that exhibits temperature dependency of CRSS expressed by Equation (1).

Equation (5) is calculated when the maximum shear stress that is obtained by substituting a size of a crystal for Equation (3) is equalized to CRSS in Equation (1): R=0.46·exp(3E3·T ⁻¹−2E−3·T).   (5)

Equation (5) indicates a cooling rate for each temperature in a cooling process where the maximum shear stress is equal to CRSS of the primary slip system for each temperature. Equation (5) was input to a temperature controller in a heat treatment furnace for use with annealing, and the cooling rate given by Equation (5) according to temperatures of the CaF₂ single crystal measured by a thermocouple, etc., was continuously changed for post-annealing cooling.

FIG. 5 is a view showing a cooling rate 101A given by Equation (5) for each temperature, together with an exemplary cooling rate 102A calculated by the conventional empirical rule. Since the present invention thus identifies the maximum shear stress permissible in a non-deformable range for each temperature and a resultant cooling rate, the cooling rate may be continuously varied as shown by the line 101A shown in FIG. 5.

On the other hand, the prior art has empirically determined a permissible cooling rate through extensive tests and resultant birefringence amounts. Indeed, the prior art calculated cooling rates at several points in the temperature ranges for the cooling process. Even when the ideal cooling temperature was calculated for each temperature which may determine the cooling rate, the cooling rate inevitably became stepwise or discontinuous, as shown in the conventional example 102A shown in FIG. 5. It was not guaranteed that the cooling rate empirically obtained for each temperature is below the permissible cooling rate, and, thus, the cooling rate should be lower than necessary in order to assure stable quality.

On the contrary, the instant embodiment may precisely calculate a cooling rate that starts generating plastic deformation due to the thermal stress, and may continuously increase the cooling rate as cooling progresses. The instant embodiment eliminates unnecessary margins and consequently enables cooling to end in almost the shortest time.

FIG. 6 is a view showing temperature of a CaF₂ single crystal over time when the CaF₂ single crystal is cooled at cooling rates shown in FIG. 5. A line 101B corresponds to cooling according to a line 101A shown in FIG. 5, which finishes in five hundred seventy-five hours as the shortest cooling time within a range of the permissible maximum shear stress. On the other hand, the line 102B shows that the cooling rate varies non-ideally, requiring extra time for cooling.

As discussed, the inventive cooling may avoid plastic deformation of a CaF₂ single crystal subject to the thermal stress during cooling, and may provide control so as to minimize the residual strain after cooling, thereby lowering the birefringence amount. Moreover, the largest cooling rate is available within a range that does not cause the plastic deformation, and a high-quality CaF₂ single crystal may be manufactured by good productivity and reproducibility.

When precise temperature control cannot always be expected due to temperature measurement errors, etc., use of Equation (6) in which the maximum shear stress given by Equation (3) becomes about 90% of the CRSS in Equation (1), instead of Equation (5), would enable a high-quality CaF₂ single crystal to be manufactured by good productivity and reproducibility: R=0.42·exp(3E3·T ⁻¹−2E−3·T).   6)

As a result of measurements using light having a wavelength of 633 nm before and after annealing of a CaF₂ single crystal cooled at a cooling rate given by Equations (5) and (6) after annealing, it was confirmed that the birefringence amount lowered from 3 nm/cm to 0.5 nm/cm within an average value of birefringence in an optical axis direction of Φ330 mm.

The instant embodiment provides an anneal apparatus with a compulsory cooling mechanism so as to maintain a sufficient cooling rate perpendicularly in a low temperature region, below 300° C. FIG. 7 is a schematic view of the anneal apparatus used for the instant embodiment. In FIG. 7, 1 is a chamber in an anneal kiln, 2 is a heat insulation material, 3 is a heater, 4 is a crucible, 5 is CaF₂, and 6 is an exhaust system. An air introduction system 7 was provided as the compulsory cooling mechanism so as to enable a proper amount of temperature-controlled gas to be introduced into the chamber. Preferably, introduced gas is inert gas, such as Ar. A method of cooling CaF₂ with temperature controlled liquid, such as water, through a cooling pipe installed in the apparatus, may be used instead of a method of introducing gas. A provision of such a compulsory cooling mechanism would provide a sufficient cooling rate in the low temperature region, particularly, below 300° C.

Such a compulsory cooling mechanism is applicable to purification and growth steps in crystal manufacture, as well as shape-processing, cleansing and film forming steps of a crystal. This mechanism may sufficiently enhance a cooling rate in the low speed region, improving productivity.

Second Embodiment

A description will be given of heat treatment to CaF₂ in a second embodiment.

According to the control of the first embodiment, the maximum shear stress in the cooling process does not exceed the CRSS of the primary slip system so as to completely eliminate deformation of a CaF₂ single crystal subject to a thermal stress during cooling after annealing. However, when an increased amount of the resultant birefringence caused by any slight deformation is actually permissible in using CaF₂, it is advantageous for productivity purposes to use the cooling rate corresponding to the maximum shear stress that exceeds CRSS at a certain ratio.

Preferably, a permissible birefringence amount is mainly determined by a wavelength of a light source of an exposure apparatus that uses a CaF₂ single crystal for a lens, for example, below I nm/cm for an ArF light source having a wavelength of 193 nm and below 0.7 nm/cm for an F₂ light source.

While an empirical approach might be the only way of obtaining an amount of the birefringent index when the maximum shear stress exceeds, at various ratios, CRSS in the primary slip system in a CaF₂ single crystal, the instant embodiment has discovered, as a result of various researches, that the birefringent index poses no working problem when the maximum shear stress is maintained to be about 1.2 times as large as CRSS.

In order to control cooling so that the maximum shear stress caused by a thermal stress in the cooling process is 1.2 times as large as CRSS in the primary slip system, the cooling process of a CaF₂ single crystal having the same material and size as those of the first embodiment uses, for example, a cooling rate obtained from Equation (7), in which the maximum shear stress given by Equation (3) is made as large as 120% of CRSS in Equation (1): R=0.55·exp(3E3·T ⁻¹−2E−3·T).   (7)

As a result of measurement using light having a wavelength of 633 nm before and after annealing of a CaF₂ single crystal cooled at a cooling rate given by Equation (7) after annealing, it was confirmed that the birefringence amount lowered from 3 nm/cm to 0.7 nm/cm, which is a practically insignificant birefringent index within an average value of birefringence in an optical axis direction of 4) 330 mm.

Third Embodiment

A description will be given of a heat treatment to CaF₂ in a third embodiment.

A post-anneal cutting step for shaping a CaF₂ single crystal into a lens maintains 300° C. or higher for cutting so as to prevent damage of CaF₂, because CaF₂ is hard and fragile in the low temperature region below 300° C. However, rapid heating and cooling in the steps of heating CaF₂ above 300° C., cutting the same, and then cooling the same would cause the maximum shear stress in CaF₂ to exceed CRSS in the primary slip system, generating plastic deformation. As a consequence, the strain increases, and the birefringence amount enlarges. The following process was designed to eliminate this problem.

For example, in cutting a CaF₂ single crystal annealed in the first embodiment into a size having a diameter of 320 mm and a thickness of 60 nm, Equation (8) is available by equalizing to CRSS in Equation (1), the maximum shear stress obtained by substituting a size of a crystal for Equation (3): R=0.46·exp(3E3·T ⁻¹−2E−3·T).   (8)

Equation (8) indicates a heating rate and a cooling rate for each temperature at which the maximum shear stress is equal to CRSS of the primary slip system. For temperature control, Equation (8) was input to a temperature controller in a cutting machine, and the heating rate before cutting and the cooling rate after cutting were continuously varied by rates given by Equation (8) according to temperatures of a CaF₂ single crystal measured by a thermocouple, etc. Such temperature control may maintain the maximum shear stress below CRSS of the primary slip system during the cutting process. Temperature control of CaF₂ at the time of cutting is also important; the temperature control over a retainer and a processing tool was conducted without causing a temperature distribution inside CaF₂. As a result of birefringence measurement using light having a wavelength of 633 nm before and after the cutting process in the instant embodiment, it was confirmed that the birefringence amount does not change from 0.5 nm/cm in an optical axis direction of Φ320 mm.

The above process control method is applicable to grinding and polishing processes, as well as the cutting process.

Fourth Embodiment

A description will be given of a heat treatment to CaF₂ in a fourth embodiment.

There is the step of cleansing a CaF₂ surface prior to the steps of forming an antireflection coating and a reflective coating. A surface absorption that results form organic deposit, residual abrasive and surface imperfection of CaF₂ is a particularly big issue in a vacuum ultraviolet region. In order to remove this surface absorption, CaF₂ is subject to a wet processing and a dry processing. In particular, the dry processing employs a processing method that causes temperature changes, such as ozone cleansing. Therefore, rapid heating and cooling in the cleansing process would cause the maximum shear stress in CaF₂ to exceed CRSS in the primary slip system, generating plastic deformation. The strain consequently increases, and the birefringence amount enlarges. The following process was designed to eliminate this problem.

Suppose that CaF₂ having a diameter of 300 mm and a maximum thickness of 50 mm obtained from the above series of steps is wet-cleansed, and then dry-cleansed by heating CaF₂ up to 400° C. in a dry cleaner. Equation (9) is obtained by equalizing to CRSS in Equation (1) the maximum shear stress obtained by substituting a size of a crystal for Equation (3): R=0.67·exp(3E3·T ⁻¹−2E−3·T).   (9)

For temperature control, Equation (9) was input to a temperature controller in a dry cleaner, and a heating rate before cleansing and a cooling rate after cleansing were continuously varied by rates given by Equation (9) according to temperatures of a CaF₂ single crystal measured by a thermocouple, etc. Such temperature control may maintain the maximum shear stress below CRSS of the primary slip system during cleansing. Temperature control of CaF₂ at the time of cleansing is also important, and a retainer, a dry cleansing tool condition, etc., were controlled so as not to cause a temperature distribution inside CaF₂. As a result of measurement of the birefringence using light having a wavelength of 633 nm before and after cleansing in the instant embodiment, it was confirmed that the birefringence amount does not change from 0.5 nm/cm in an optical axis direction of Φ300 mm.

Fifth Embodiment

A description will be given of a heat treatment to CaF₂ of a fifth embodiment.

The steps of forming an antireflection coating and a reflecting coating on a CaF₂ surface maintain the temperature of CaF₂ from about 200° C. to about 400° C. for better coating characteristics, and form a coating through resistance-heating evaporation, electron-beam evaporation, and sputtering. Rapid heating and cooling in the coating process would cause the maximum shear stress in CaF₂ to exceed CRSS in the primary slip system, generating plastic deformation. The strain consequently increases, and the birefringence amount enlarges. The following process design was conducted to overcome this problem.

Suppose that CaF₂ having a diameter of 300 mm and a maximum thickness of 50 mm obtained from the above series of steps is accommodated in a coating apparatus. Equation (9) is applicable to a coating process of magnesium fluoride at 400° C. by evaporation.

For temperature control, Equation (9) was input to a temperature controller in a coating apparatus for a CaF₂ single crystal, and a heating rate before a coating and the cooling rate after the coating were continuously varied by rates given by Equation (9) according to temperatures of a CaF₂ single crystal measured by a thermocouple, etc. Such temperature control may maintain the maximum shear stress below CRSS of the primary slip system during the coating process. Temperature control of CaF₂ at the time of coating is also important, and a retainer, an arrangement of a heater, etc., were controlled so as not to cause a temperature distribution inside CaF₂. As a result of measurement of the birefringence using light having a wavelength of 633 nm before and after the coating process in the instant embodiment, it was confirmed that the birefringence amount does not change from 0.5 nm/cm in an optical axis direction of Φ300 mm.

Sixth Embodiment

A description will be given of a heat treatment to CaF₂ in a sixth embodiment.

As discussed, control over a temperature variation rate, so that thermal stress inside a CaF₂ single crystal does not substantially exceed CRSS of the primary slip system, is effective in preventing an increase of birefringent index in heating and cooling a CaF₂ single crystal. However, as an optical element made of a CaF₂ single crystal used for an exposure apparatus becomes larger, the cooling rate should be lowered to maintain the thermal stress to be constant. As a wavelength of a light source used becomes shorter, influence of the birefringence increases and the precise temperature control becomes required. In particular, in controlling post-anneal cooling for an optical element that is made of a CaF₂ single crystal and has a large aperture of Φ300 mm or larger, a cooling rate in a high temperature region becomes 0.5° C./hour or less, the productivity deteriorates, and the temperature control begins to pose problematic precision. In particular, an optical element for an F₂ laser light source having a short wavelength is subject to influence of changes of birefringent index with even slight erroneous temperature control.

In order to eliminate these problems, improved CRSS of the slip system in a CaF₂ single crystal and increased permissible thermal stress are effective. A description will be given of manufacturing a high-quality optical element by improving deformation tolerance of a CaF₂ single crystal.

As shown in FIG. 4, CRSS in the {0 0 1}<1 1 0> slip system as the primary slip system increases as the strontium content increases in the CaF₂ single crystal. Equation (10) is an equation that defines temperature dependency of CRSS in the {0 0 1}<1 1 0> slip system of a CaF₂ single crystal that contains 600 ppm of strontium. τ_(c) ^(1ST)=2.0E−2·exp(3E3·T ⁻¹)   (10) where τ_(c) is CRSS [MPa] and T is temperature [K].

When the strontium content is 100 ppm, Equation (10) exhibits CRSS that is about 1.3 times as large as that in Equation (1). As disclosed in Japanese Patent Application Publication No. 9-255328, strontium of about 600 ppm in CaF₂ does not negatively affect the optical performance of CaF₂.

Suppose that a CaF₂ single crystal, which has a cylindrical shape with a diameter of 330 mm and a maximum thickness of 60 mm, is manufactured similar to that in the first embodiment, and includes strontium of 500 ppm, is cooled after annealing. Equation (11) is obtained by equalizing to CRSS in Equation (10) the maximum shear stress obtained by substituting a size of a crystal in Equation (3): R=0.62·exp(3E3·T ⁻¹−2E−3·T).   (11)

Equation (11) was input to a temperature controller in a heat treat furnace, and the cooling rate was continuously varied for post-anneal cooling by the cooling rate given by Equation (11) according to temperatures of a CaF₂ single crystal measured by a thermocouple, etc.

As a result of measurements using light having a wavelength of 633 nm before and after annealing of a CaF₂ single crystal cooled at a cooling rate given by Equations (1 1) after annealing, it was confirmed that the birefringence amount lowered from 3nm/cm to 0.5 nm/cm within an average value of birefringence in an optical axis direction of Φ300 mm. The time period necessary for cooling was about five hundred seventy-five hours in the first embodiment, while it was about four hundred thirty-one hours in the instant embodiment. The cooling rate at the cooling start time at 100° C. was able to increase from 0.38° C./hour to 0.51 ° C./hour.

Thus, an addition of strontium as a third element in addition to fluorine and calcium that make up CaF₂ may improve CRSS in the primary slip system of a CaF₂ single crystal, thereby shortening a post-anneal cooling time, while maintaining the optical performance of CaF₂ after annealing, and improving controllability with an improved cooling rate. Preferably, the added element amount is larger for improvement of CRSS, in particular, above I 00 ppm. The added element is not limited to strontium, as far as the addition does not deteriorate the optical performance.

Seventh Embodiment

A description will be given of an exposure apparatus that uses CaF₂ for an optical system of one embodiment according to the present invention.

FIG. 8 shows a schematic diagram of an optical system in the exposure apparatus of the instant embodiment. Reference numeral 11 is an ultraviolet light source, such as a KrF, an ArF, an F₂ and an Ar₂ laser. A beam 13 from the light source 11 is introduced into an illumination optical system 14 through a mirror 12, and light that passes through the illumination optical system illuminates a reticle 15 as a first object. The light having information of the reticle 15 is projected onto a photosensitive plate 17 through a reduction projection optical system 16.

The illumination and projection optical systems in the exposure apparatus of the instant embodiment use CaF₂ prepared by the inventive heat treatment method. Since the inventive CaF₂ has a lower birefringence than conventional CaF₂, good imaging performance with high contrast may be obtained. Therefore, use of the exposure apparatus of the instant embodiment would be able to transfer a fine and clear pattern onto a photosensitive plate.

Eighth Embodiment

A description will be given of a method of manufacturing a semiconductor devices using the inventive exposure apparatus.

FIG. 9 is a flowchart for explaining a fabrication of a device (i.e., semiconductor chips such as ICs and LSIs, LCDs, CCDs, etc.). Here, a description will be given of a fabrication of a semiconductor chip as an example. Step 1 (circuit design) designs a semiconductor device circuit. Step 2 (mask fabrication) forms a mask having a designed circuit pattern. Step 3 (wafer preparation) manufactures a wafer using materials such as silicon. Step 4 (wafer process), which is referred to as a pretreatment, forms actual circuitry on the wafer through photolithography using the mask and wafer. Step 5 (assembly), which is also referred to as a post-treatment, forms into a semiconductor chip the wafer formed in Step 4 and includes an assembly step (e.g., dicing, bonding), a packaging step (chip sealing), and the like. Step 6 (inspection) performs various tests for the semiconductor device made in Step 5, such as a validity test and a durability test. Through these steps, a semiconductor device is finished and shipped (Step 7).

FIG. 10 is a detailed flowchart of the wafer process in Step 4 shown in FIG. 9. Step 11 (oxidation) oxidizes the wafer surface. Step 12 (CVD) forms an insulating film on the wafer's surface. Step 13 (electrode formation) forms electrodes on the wafer by vapor deposition, and the like. Step 14 (ion implantation) implants ions into the wafer. Step 15 polishes and flattens a surface of the wafer using a chemical mechanical polishing machine.

Step 16 (resist process) applies a photosensitive material onto the wafer. Step 17 (exposure) exposes the pattern on the mask onto the wafer. Step 18 (development) develops the exposed wafer. Step 19 (etching) etches parts other than a developed resist image. Step 20 (resist stripping) removes unused resist after etching. These steps are repeated, and multilayer circuit patterns are formed on the wafer. The device fabrication method of this embodiment may manufacture a higher quality device than does the conventional method. Claims for a device fabrication method for performing operations similar to those of the above exposure apparatus cover devices as intermediate and final products. Such devices include semiconductor chips such as LSIs and VLSIs, CCDs, LCDs, magnetic sensors, thin film magnetic heads, and the like.

Use of the inventive manufacturing method for wafer processing would be able to manufacture highly integrated semiconductor devices, which have previously been hard to manufacture.

As discussed, a basic cooling condition that does not generate birefringence is clarified by paying attention to a mechanism that increases the birefringent index in the cooling process, and a manufacturing method that stably manufactures CaF₂ of good quality with good productivity may be provided.

CaF₂ having a large size, which is likely to increase birefringence, may be manufactured with high quality and good productivity.

In addition, the present invention may provide an optical system made of the thus prepared CaF₂ having excellent contrast, an exposure apparatus using the same, and a device fabrication method using the exposure apparatus for a manufacturing step. 

1-9. (canceled)
 10. A calcium fluoride single crystal for photolithography, wherein a critical resolved shear stress (τ_(c)) in a <1 1 0> direction on a {0 0 1} plane of the calcium fluoride single crystal is approximately equal to or larger than a shear stress (τ) expressed by τ=1.5E−2·exp(3E3·T⁻¹), where τ is shear stress (MPa) and T is average temperature (K) of the calcium fluoride.
 11. A calcium fluoride single crystal according to claim 10, wherein said calcium fluoride single crystal for photolithography has a diameter having Φ300 mm or larger and is used for a specific wavelength band less than 160 nm.
 12. A calcium fluoride single crystal according to claim 10, comprising one or more types of additional elements with a concentration of 20 ppm or larger.
 13. A calcium fluoride single crystal according to claim 12, wherein the additional elements include strontium having a concentration of 20 to 600 ppm. 14-21. (canceled) 